WO2005116445A1

WO2005116445A1 - Method for controlling and adjusting a wind turbine

Info

Publication number: WO2005116445A1
Application number: PCT/EP2005/004842
Authority: WO
Inventors: Eberhard Voss
Original assignee: Nordex Energy Gmbh
Priority date: 2004-05-18
Filing date: 2005-05-04
Publication date: 2005-12-08
Also published as: CN101094985B; BRPI0511439A; CA2568310C; US7566982B2; EP1747375A1; EP1747375B1; JP4764422B2; ES2327546T3; AU2005248021B2; DE102004024564A1; RU2006143319A; JP2007538190A; NO20065703L; US20090079192A1; RU2350778C2; ATE432415T1; DE102004024564B4; DE502005007359D1; AU2005248021A1; AU2005248021B9

Abstract

The invention relates to a method for controlling and adjusting a wind turbine comprising a machine housing that can be displaced by an azimuth angle, at least one rotor blade that can be displaced about its longitudinal axis and a power supply for a spin mode. Said method comprises the following steps: a control unit determines an angular position for the machine housing and one or more displacement angles for the rotor blade or blades from measured values (v) for the wind speed and the wind direction; if a measured wind speed exceeds a predetermined speed value (v1*, v2*), at least one azimuth drive that is fed by the power supply displaces the machine housing into the angular position (α) that has been determined by the control unit and at least one pitch drive that is fed by the power supply displaces the rotor blade or blades into the angular position (ζ) that has been determined by the control unit. When in the set position, the rotor blade or blades rotate(s) at a speed in a predetermined speed range.

Description

METHOD FOR CONTROLLING AND CONTROLLING A WIND ENERGY SYSTEM

The present invention relates to a method for controlling and regulating a wind turbine and the wind turbine itself.

From DE 195 32 409 AI a method for operating a wind turbine is known, with which the yield of the wind turbine increases and at the same time the load can be limited at higher wind speeds. For this purpose, the power of the wind turbine is reduced from a predetermined Abschaltwindgeschwindigkeit by the operating speed of the rotor of the wind turbine is limited. In the known wind turbine this is not completely turned off when reaching the limit speed, but the Wmdenergieanlage is forcibly reduced in operating speed as soon as a flow velocity is above the value of the limit speed. The wind turbine is thus operated above the usual "shutdown" on, so that the performance curve is extended to greater wind speeds and the energy yield and the network compatibility of the wind turbine is improved.

From EP 1 286 049 A2 a wind turbine with pitch-controlled rotor blades is known. For the wind turbine, a stationary parking position is provided, in which the load on the wind turbine is reduced. The wind turbine is stabilized in the parking position by an active control of the rotor blade adjustment. If, for example, turbulence-induced emigration of the rotor blade occurs from the parking position, then a control intervention which counteracts this emigration follows. For this purpose, the twisting range of the rotor blades is extended, so that these, based on a conventional direction of rotation of the rotor, can generate an opposite torque.

From DE 100 58 076 C2, a method for controlling a wind power plant is known, in which above a shutdown speed, the nacelle is brought into a predetermined azimuth position, wherein at the same time the rotor blades for the azimuth position are brought into their flag position. In particular, the use of an azimuth brake and a rotor brake is dispensed with in the control method, so that the oncoming wind automatically sets the lee-side rotor in the position with the lowest wind resistance. In the known method it is avoided that by adjusting an azimuth position, the rotor blades brought into their feathering position are tracked relative to the main wind direction.

The invention has for its object to provide a method for controlling a wind turbine, which reduces the load of the wind turbine at high wind speeds and ensures a substantial supply of the wind turbine at a possible failure of the power grid.

The object of the invention is achieved by a method having the features of claim 1. Advantageous embodiments are shown in the subclaims.

The inventive method relates to the control and regulation of a wind turbine, which has a nacelle, at least one rotor blade and a power supply. The nacelle is adjustable in its azimuth. The one rotor blade or the multiple rotor blades are each adjustable about their longitudinal axis, this adjustment is called pitch adjustment designated. In the inventive method for a whirl operation, a control unit determines an angular position for the engine house from measured values for the wind speed and the wind direction and one or more adjustment angles for the at least one rotor blade when a measured wind speed exceeds a certain speed value. In this predetermined by the exceeding of a predetermined speed value operating mode of the wind turbine are calculated by the control unit target angle for azimuth and pitch adjustment. The predetermined angular adjustment is adjusted by an azimuth drive and a pitch drive, both drives being powered by the power supply. The control unit determines the angle to be set such that the at least one rotor blade rotates at a speed from a predetermined speed range. The invention is based on the approach that also in the operating mode according to the invention continues to rotate, so that in strong wind, the system is lightly loaded and / or can continue to be generated via an auxiliary generator energy. The inventive method has two essential applications. In the one case in which the power supply is ensured for example by the electrical network or otherwise, the predetermined speed value is selected to be high, for example in the range of the shutdown speed, so that at high wind speeds, the wind turbine enters the spinning mode. In this case, the rotor is not stopped, but can continue to rotate at a low speed. In a second application of the method according to the invention, the electrical network or the connection to this failed, so that the electrical energy generated by the generator can no longer be fed and consumers in the wind turbine can not be permanently supplied. In this case, a very low predetermined speed is selected, so that the method according to the invention is also used in regular wind conditions. Here Then the wind turbine turns at a speed from a predetermined speed range and thus generates the necessary energy supply in the spinning mode.

In a preferred embodiment, the control unit for the at least one rotor blade determines the setpoint or values for displacement angles depending on the calculated azimuth angle and other variables, such as actual value of the rotational speed, wind direction and wind speed. When measured wind direction or in certain main wind direction for changing wind directions of the pitch angle is determined at least taking into account the setpoint of the predetermined azimuth angle and / or an actual value of the speed.

In an above-mentioned variant of the method according to the invention, the power supply via the power grid, with which the wind turbine is connected. In this case, there is sufficient power supply for the consumers of the wind turbine, such as control unit, drives, measuring sensors, communication equipment and the like, to a sufficient extent, so that an emergency or auxiliary power supply is not required. The transition into the spinning mode takes place when a correspondingly large value for the predetermined wind speed is exceeded, wherein the predetermined speed value (v _t ) corresponds approximately to the turn-off speed of the wind turbine.

In the second embodiment, an auxiliary generator is provided, which is designed for the power supply in the predetermined rotational speed range of the spinning operation and whose input shaft is coupled to a shaft driven by the rotor. In this embodiment of the method according to the invention, the auxiliary generator obtains the necessary for the supply of electrical power from the Rotation of the rotor in spinning mode. Preferably, in this case, the predetermined speed range has low speeds compared to the regular operation of the wind turbine. Alternatively, the predetermined speed range may also have rotational speeds, as present in the regular operation of the wind turbine. In this case, a generator intended for regular operation preferably serves as an auxiliary generator.

Preferably, the auxiliary generator is designed so that at least a portion of the electrical load in the wind turbine can be permanently supplied by this.

In case of failure of the network connected to the wind turbine, the predetermined value for the wind speed is preferably set to a low value such that the auxiliary generator can supply a part of the consumers of the wind turbine. Here, the predetermined value corresponds approximately to the turn-on speed of the wind turbine. The control unit for the at least one rotor blade preferably determines the setpoint value (s) for the adjustment angle depending on a power requirement of the consumers to be supplied in the wind energy plant.

The object according to the invention is likewise achieved by a wind energy plant itself. The wind turbine has a nacelle, at least one rotor blade and a control unit. The nacelle is adjustable in its angular orientation by means of at least one azimuth drive. The one rotor blade or the plurality of rotor blades of the wind energy plant are each adjustable in their angular position about the longitudinal axis via one or more pitch drives. At the control unit are the measured values of wind strength and wind direction and can be processed by this. Above a predetermined Wind speed are controlled in a spin operation, the drives such that the nacelle and the at least one rotor blade in a predetermined by the control unit angular position, preferably in the wind, is provided, wherein in the set angular position, the at least one rotor blade at a speed in a predetermined Area turns. Preferably, the wind turbine according to the invention is provided with an electric generator for a predetermined speed range, which is powered by the at least one rotor blade for power and which supplies at least a portion of the electrical loads, in particular at least control unit, wind sensor, azimuth and pitch drive.

Three possible embodiments of the method according to the invention are explained below with the aid of three flow charts. It shows:

1 shows a flow chart for the method according to the invention, which switches over to a controlled spinning mode when a predetermined value V ₁ for the wind speed is exceeded,

2 shows the sequence of the method according to the invention, which switches to the controlled spinning mode in the event of a power failure, and

Fig. 3 shows a control method that switches both at a first wind speed vi and in case of power failure in a controlled spinning operation to supply the consumers of the wind turbine.

With reference first to FIG. 1, the method according to the invention is initialized in a method step 10. In a subsequent query 12, the control unit checks whether the values for the measured wind speed v are greater than a predetermined value

are for the wind speed. The measured value of the wind speed may be a current value or a value averaged over a time interval so as to compensate for short-term variations in wind speed. The predetermined value for the wind speed V _\ preferably sets about the size of the usual shutdown speed for the wind turbine, in which due to the large wind strength no regular operation can be done.

If the measured wind speed v exceeds the predetermined limit value for the wind speed v _t , the control unit calculates in a subsequent step 14 a target value for the azimuth angle α_Soll and the pitch angle φ_Soll of the rotor blades. For a uniform loading of the rotor blades, all rotor blades are preferably moved into the same pitch position. The setpoint values α setpoint and φ setpoint are calculated here in such a way that the wind energy plant decelerates from its current speed to a lower speed value after the setpoint values determined by the control unit have been set in step 16. The wind turbine then rotates at a low but predetermined speed. Not shown in Fig. 1 is a control that can be provided to stabilize the predetermined speed. If the speed achieved by the angles α and φ deviates upwards or downwards from the predetermined speed interval, a control intervention takes place to the effect that the speed returns to the desired speed range. The machine housing remains facing the wind in this process.

The particular advantage of the method shown in Fig. 1 is that the wind energy plant is stable even during storm by the spinning operation at a low speed. The slow rotation of the rotor prevents tensions and forces from building up due to the incoming wind or storm that causes the Wind turbine can damage. Also, sudden gusts are no longer critical due to the rotation of the rotor blades. The spinning operation increases the stability of the wind turbine, so that it can be designed accordingly.

FIG. 2 shows a further application of the controlled spinning operation, in which, after an initialization 18 in a query 20, it is checked whether the electrical network to which the wind energy plant is connected for supplying electrical energy is available. If the electrical network is present, it is possible in method step 22 to proceed with a further control or regulation, for example also with the method illustrated in FIG. 1, as will be described in more detail below. If the electrical network has failed, it is checked in step 24 whether a measured wind speed v is greater than a predetermined minimum wind speed v. The minimum speed v ₂ is in this case dimensioned so that a power supply of the electrical load in the wind turbine can be done by an auxiliary generator from the wind. If the measured wind speed does not exceed the predetermined minimum value for the wind speed, in step 26 the steps necessary for securing the wind turbine are initiated in the event of a power failure. These may include placing the rotor blades in the flag position, securing and shutting down the control unit, starting emergency generators, and the like.

However, in the event of a power failure, if the power to be extracted from the wind is sufficient to generate sufficient electrical energy for the wind turbine via an auxiliary generator connected to the rotor, the control unit determines target values for the azimuth and the pitch angle in step 28, that the wind turbine is running at a suitable speed for the auxiliary generator, after the predetermined angles and φ have been adjusted in step 30. The use of an electric auxiliary generator driven by the rotor in the event of a power failure enables the wind energy plant to provide sufficient energy independently of an external supply or auxiliary equipment connected to supply the electrical consumers and thus remain permanently functional.

Fig. 3 shows a particularly preferred combination of both methods. In the method illustrated in FIG. 3, after an initialization of the method in step 32, first in step 34 a query is made as to whether a power supply can be provided from the electrical network or from the current regularly generated by the generator.

If the query 34 indicates that a sufficient power supply is available, it is checked in the following step 36 whether the measured wind speed exceeds a predetermined value v ₁ . If this is not the case, then this part of the method returns via the branch 38 in its starting position and it can be a regular control or regulation of the wind turbine for maximum power (not shown).

On the other hand, if the measured wind speed v exceeds the predetermined value v ₁ , first set values for the azimuth and the pitch angle (α_soll_l and φ_soll_l) are calculated in step 40. These angles are determined by the control unit so that the wind turbine is braked after setting the angle in step 42 to a predetermined speed range. With the angles α_l and φ_l a stable spinning operation is achieved in which in strong wind (V> VΪ) the wind energy turbine is spinning. If, on the other hand, it is determined in query 34 that the electrical network has failed, a query is made in step 44 as to whether the wind speed is high enough to supply sufficient electrical power via an auxiliary generator. If this is not the case, similar to the method of FIG. 2 in step 46, the corresponding emergency measures for securing the wind turbine are initiated.

However, if query 44 indicates that the wind is strong enough (v> v ₂ *) to gain sufficient electrical power to power the wind turbine with the auxiliary generator, then in step 48 the corresponding azimuth and pitch angle setpoints ( α_Soll_2, φ_Soll_2). After setting these angles in method step 50, the auxiliary generator generates the electrical power sufficient for the operation of the wind energy plant without feeding it into the grid.

For the sake of simplicity, in the above examples, the controlled whirling operation of the wind turbine was described only for driving the azimuth and pitch angles. It was assumed that the wind turbine changes after a certain period in the predetermined speed range. But it can also be controlled to the predetermined speed range, for example, by measuring the actual value of the speed and taken into account in the determination of the setpoint values for the angle.

Claims

Claims:

1. A method for controlling and regulating a wind turbine with an adjustable by an azimuth angle nacelle, at least one adjustable about its longitudinal axis rotor blade and a power supply in a spinning operation, the method comprising the steps of: - a control unit determined from measured values (v) for the wind speed and the wind direction, an angular position for the nacelle and one or more displacement angles for the at least one rotor blade when a measured wind speed exceeds a predetermined speed value (v, v ₂ ), - at least one azimuth drive powered by the power supply provides the nacelle in the determined by the control unit angular position (α) and at least one powered by the power pitch drive, the at least one rotor blade in the determined by the control unit angular position (φ), wherein the at least one rotor blade in the set Posit ion rotates at a speed from a predetermined speed range.

2. The method according to claim 1, characterized in that the control unit for the at least one rotor blade determines the setpoint or values for the adjustment angle as a function of at least the calculated azimuth angle and / or the actual value of the rotational speed.

3. The method according to claim 1 or 2, characterized in that the power supply via the power grid, with which the wind turbine is bound, wherein the predetermined speed value (\\) approximately corresponds to the turn-off speed of the wind turbine.

4. The method according to any one of claims 1 to 3, characterized in that an auxiliary generator is provided, which is designed for the power supply in the predetermined speed range and whose input shaft is coupled to a shaft driven by the rotor.

5. The method according to claim 4, characterized in that in case of failure of the network connected to the wind turbine, the predetermined value for the wind speed is set to a value (v ₂ ) such that the auxiliary generator can supply at least a portion of the consumers of the wind turbine.

6. The method according to claim 5, characterized in that the predetermined value (v ₂ ) corresponds approximately to the turn-on speed of the wind turbine.

7. The method according to any one of claims 4 to 6, characterized in that the predetermined speed range has low speeds compared to a regular operation of the wind turbine.

8. The method according to any one of claims 4 to 6, characterized in that the predetermined speed range has rotational speeds, as they occur in a regular operation of the wind turbine.

9. The method according to any one of claims 4 to 8, characterized in that a generator intended for regular operation is provided as the auxiliary generator.

10. The method according to any one of claims 4 to 9, characterized in that the auxiliary generator is designed to supply at least a portion of the electrical load in the wind turbine, said consumer comprising at least control unit, wind sensor, azimuth and pitch drive.

11. The method according to any one of claims 4 to 10, characterized in that the control unit for the at least one rotor blade or setpoint values for the adjustment determined depending on a power requirement of the electrical consumers to be supplied in the wind turbine.

12. Wind energy plant with a nacelle, which is adjustable in at least one azimuth drive in its angular orientation, with at least one rotor blade, which is adjustable by one or more pitch drives in its angular position about its longitudinal axis, with a control unit to the measured Wind power and wind direction values are applied, and with a power supply that supplies at least the drives with electrical power, characterized in that in a whirling operation above a predetermined wind speed (vi ^* , v ₂ ^* ), the control unit controls the drives such that the The machine house and the at least one rotor blade are in an angular position predetermined by the control unit such that the at least one rotor blade rotates at a speed from a predetermined speed range.

3. Wind turbine according to claim 12, characterized in that a designed for the predetermined speed range electrical generator is provided, which is powered by the at least one rotor blade for power supply and supplies at least a portion of the electrical load of the wind turbine, said consumer at least control unit, wind sensor , Azimuth and pitch drive include.